Editing method of dynamic spectrum program

ABSTRACT

The present invention relates to an editing method of a dynamic spectrum program, which includes the following steps. Downloading the spectral recipe is to download the spectral recipe with multi light scene with specific color temperature or at least one specific color temperature to the editing device through the internet, and connect the editing device with the software as a service system or platform as a service system configured in the cloud. Perform the correlation editing between the specific function and the spectral recipe. The editing device divides the specific function to be achieved into multiple blocks through the software as a service system or the platform as a service system, and the blocks correspond to the spectral recipe of the multi light scene respectively. And forming a functional dynamic spectrum program, which is to configure multiple blocks for corresponding time to form a dynamic spectrum program.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. 63/190,426, filed May 19,2021, which is incorporated in its entirety by reference herein.

FIELD OF THE INVENTION

The present invention relates to an editing method of dynamic spectrumprogram, in particular to an editing method of dynamic spectrum programthrough software as a service (SaaS) system or platform as a service(PaaS) system configured in the cloud.

BACKGROUND OF THE INVENTION

Humans are animals with changeable emotions, they will have differentemotional reactions with the individual's psychological state, such asexcitement, amusement, anger, disgust, fear, happiness, sadness, serene,neutral. When negative emotions (such as anger, disgust and fear) cannotbe resolved in time, they will cause psychological damage or trauma tothe human body, and finally evolve into mental illness. Therefore, howto timely provide an emotional resolution or relief or treatment systemthat can meet the needs of users has broad business opportunities intoday's society, full of high competition and high pressure at any time.

In modern medical equipment, the changes of hemodynamics caused byneuronal activity can be measured by functional Magnetic ResonanceImaging (fMRI) system. Due to the non-invasiveness of fMRI and its lowradiation exposure, fMRI is currently mainly used in the study of humanand animal brain or spinal cord. At the same time, the tester can alsobe checked by the electroencephalogram of the EEG, and the emotions canbe stimulated in the same way, and the responses of different emotionscan be seen, for example, the brainwave patterns of fear and happinesscan be seen significantly different. Among them, when observing theresponse of a certain emotion under fMRI and electroencephalograph(EEG), for example, under happy emotion (which can be induced bypictures and matched with facial emotion recognition), fMRI was used toobserve the blood oxygen-level dependent (BOLD) contrast response andfound that in the Medial prefrontal cortex (Mpfc), there weresignificantly more responses to the corresponding emotions (anger andfear). In contrast, for example, in the case of fear and anger, fMRI wasused to observe the blood oxygen-level dependent (BOLD) contrastresponse, and it was found that it was significantly reflected in theamygdala region, showing that the two kinds of emotions have differentresponse regions in the brain. Therefore, the blood oxygen-leveldependent (BOLD) contrast response of different regions in the brain canbe used to clearly determine which emotion the tester is currently in.In addition, if the electroencephalogram of the EEG is used to examinethe measurement tester, and the emotions are stimulated in the same way,it can be seen that the brainwave patterns of fear and happiness aresignificantly different. Therefore, you can also judge what kind ofemotion the tester is currently in through the brainwave patterns ofdifferent reactions. According to the above, for the functional MagneticResonance Imaging (fMRI) system, emotions are distinguished by differentblood oxygen-level dependent (BOLD) contrast reactions, while for theelectroencephalograph (EEG), emotions are distinguished by differentbrainwave patterns. It is obvious that the methods used to judge theemotion of the tester and the contents recorded are completelydifferent. Therefore, in terms of current science and technology, thebrainwave patterns of electroencephalograph (EEG) cannot replace theblood oxygen-level dependent (BOLD) contrast response of functionalMagnetic Resonance Imaging (fMRI) for the test results of the sameemotion of the same tester.

The above discussion on emotion judgment by functional MagneticResonance Imaging (fMRI) system and electroencephalograph (EEG) is thatfMRI system is very expensive and huge, so it cannot be used incommercial systems and methods of human centric lighting. Similarly, ifonly the brainwave patterns of the electroencephalograph (EEG) are usedto judge the mood of the tester, it may be encountered that thebrainwave patterns of different testers for different emotions may bedifferent. Therefore, at present, it is impossible to use the bloodoxygen-level dependent (BOLD) contrast response of functional magneticresonance imaging (fMRI) system alone, or the brain wave mode ofelectroencephalograph (EEG) alone to construct a commercial humancentric lighting method and system through the editing of spectralrecipe.

SUMMARY OF THE INVENTION

According to the above description, the present invention provides amethod to establish a correlation between the brainwave pattern of anelectroencephalograph (EEG) and the blood oxygen-level dependent (BOLD)contrast of a functional Magnetic Resonance Imaging (fMRI), after whichthe brainwave pattern of an electroencephalograph (EEG) is used as ahuman centric lighting application on a commercial system.

The present invention provides an editing method of a dynamic spectrumprogram, including the following steps. Downloading the spectral recipeis to download the spectral recipe with multi light scene with specificcolor temperature or at least one specific color temperature to theediting device through the internet, and connect the editing device withthe software as a service system or platform as a service systemconfigured in the cloud. Perform the correlation editing between thespecific function and the spectral recipe. The editing device dividesthe specific function to be achieved into multiple blocks through thesoftware as a service system or the platform as a service system, andthe blocks correspond to the spectral recipe of the multi light scenerespectively, and forming a functional dynamic spectrum program, whichis to configure multiple blocks for corresponding time to form a dynamicspectrum program.

The present invention also provides a human centric lighting method ofsituational dynamic spectrum program, which includes the followingsteps. The construction of situational dynamic spectrum program databaseis to associate the spectral recipe of the multi light scene to achievea specific color temperature with the specific function to be achieved.The correlation editing is to divide the specific function to beachieved into multiple situational blocks through the cloud,respectively correspond the situational blocks to the multi light scene,and then add time to the situational blocks, form a situational dynamicspectrum program and store it in the cloud database. Selectingsituational dynamic spectrum programs is that users connect with thecloud through intelligent communication devices, and then selectsituational dynamic spectrum programs that users want to achievespecific emotions from the cloud database. Human centric lighting is tostart the multispectral light-emitting device configured in the fieldwith the lighting parameters in the selected situational dynamicspectrum program in a specific field to emit a specific colortemperature of multi spectrum, so as to perform human centric lightingto the user. Adjust the spectral recipe, after the user performs humancentric lighting, when the effect of specific emotion is not reached,the user adjusts the lighting parameters in the selected specificspectral recipe through the intelligent communication device, andstoring the adjusted situational dynamic spectrum program, which is tostore the lighting parameters in the situational dynamic spectrumprogram selected and adjusted by the user to the cloud database when theuser has achieved the effect of the specific emotion after performinghuman centric lighting.

The present invention further provides a human centric lighting methodof situational dynamic spectrum program, which includes the followingsteps. The construction of situational dynamic spectrum program databaseis to associate the spectral recipe of the multi light scene to achievea specific color temperature with the specific function to be achieved.The correlation editing is to divide the specific function to beachieved into multiple situational blocks through the cloud,respectively correspond the situational blocks to the multi light scene,and then add time to the situational blocks, form a situational dynamicspectrum program and store it in the cloud database. Selectingsituational dynamic spectrum programs is that users connect with thecloud through intelligent communication devices, and then selectsituational dynamic spectrum programs that users want to achievespecific emotions from the cloud database. Human centric lighting is tostart the multispectral light-emitting device configured in the fieldwith the lighting parameters in the selected situational dynamicspectrum program in a specific field to emit a specific colortemperature of multi spectrum, so as to perform human centric lightingto the user. To judge whether the human centric lighting reaches theeffect of specific emotion, it is to calculate the physiological signalmeasured by the contact physiological sensor configured on the user, soas to judge whether the human centric lighting reaches the effect ofspecific emotion. And storing the situational dynamic spectrum program.When it is judged that the human centric lighting has reached the effectof specific emotion, the corresponding lighting parameters of thespectral recipe of the situational dynamic spectrum program are storedin the cloud database.

The present invention has provided the process of building various“spectral recipe” and the database of “spectral recipe” buildingservices, as well as the database of hardware services and softwareservices required for the construction of “spectral recipe”, which havebeen established on the “sharing platform” of the optical environment.In particular, the “sharing platform” finally established is a “spectralrecipe” that can provide effective spectral combination of multi-lightscenes and spectral combination of multi emotional light scenes. Afterthat, it can provide various commercial services and operations throughthis common “sharing platform”.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1a is the original data collection structure of the human centriclighting to physiological and emotional according to the presentinvention.

FIG. 1b is the original data collection of the human centric lighting tophysiological and emotional according to the present invention.

FIG. 1c is the judgment flow for the response of human centric lightingto specific physiological and emotional according to the presentinvention.

FIG. 2a is a method for establishing the response of EEG of humancentric lighting to physiological and emotional.

FIG. 2b is the lighting database that the present invention constructsthe user to carry out effective human centric lighting.

FIG. 3 is the system frame diagram of the intelligent human centriclighting system of the present invention.

FIG. 4 is a method for constructing a human centric light environmentplatform of the present invention.

FIG. 5a is an automatically adjustable intelligent human centriclighting method of the present invention.

FIG. 5b is an editing process of the situational dynamic spectrumediting platform of the present invention.

FIG. 5c is a kind of situational dynamic spectrum program withconference function of the present invention; and

FIG. 6 is an intelligent human centric light system applied tocommercial operation of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In the specification after the present invention, the functionalmagnetic resonance imaging system is referred to as “fMRI system”, theelectroencephalograph is referred to as “EEG”, and the bloodoxygen-level dependent comparison is referred to as “BOLD”. In addition,in the embodiment of the color temperature test of the presentinvention, the test is carried out in units of every 100 k. However, inorder to avoid too lengthy description, in the following description,the so-called specific emotion refers to excitement or excitement,happiness, amusement, etc., and the corresponding specific emotionalresponse will be explained with 3,000 K, 4,000 K and 5,700 K as colortemperature test examples, Therefore, the present invention cannot belimited to the embodiments of the three color temperatures. At the sametime, in order to make those in the technical field of the presentinvention fully understand the technical content, relevant embodimentsand embodiments thereof are provided for explanation. In addition, whenreading the embodiment provided by the present invention, please alsorefer to the schema and the following description, in which the shapeand relative size of each component in the schema are only used toassist in understanding the content of the embodiment, not to limit theshape and relative size of each component.

The present invention uses fMRI system to understand the correspondingrelationship between spectrum and emotion in the brain throughphysiological signal measurement method, and recipetes a set ofpreliminary mechanism of using light to affect human physiological andpsychological reactions, because the brain imaging of fMRI system canjudge which part of the human brain has hyperemia reaction whenstimulated by light, it can also record BOLD reaction. This BOLDresponse to brain hyperemia is also known as the “rise of blood oxygenconcentration dependent response”. Therefore, according to the imagerecording data of brain hyperemia under various emotions of fMRI systemand the response of “rise of blood oxygen-level dependent response”, thepresent invention can accurately and objectively infer the physiologicaland emotional changes of the tester, and then take the physiological andemotional confirmed by fMRI system as the basis, Further, EEG is used torecord the changes of EEG to establish the correlation between them, inorder to use the changes of EEG to replace the emotion judgment of fMRIsystem.

Therefore, the main purpose of the present invention is to enable thetester to record the BOLD response of the tester to the specific emotionafter illuminating the tester during the test of specific emotion in thefMRI system, so as to screen out which specific “effective colortemperature” can multiply the specific emotion, The color temperature oflighting is used as the “effective color temperature” corresponding tospecific emotions. After that, the tester is illuminated with “effectivecolor temperature”, and the EEG is used to record the brainwave patternsunder the stimulation of “effective color temperature”, so that thespecific brainwave patterns of the EEG is related to the specific BOLDresponse. After that, the user's emotional change can be assisted by thespecific EEG mode of the EEG, in order to construct a set of intelligenthuman centric lighting system and its method that can be operatedcommercially, so as to solve the problem that expensive fMRI system mustbe used to execute intelligent human centric lighting system, which canreduce the operation cost and further meet the customized servicedemand.

First, please refer to FIG. 1a , which is the original data collectionframework of physiological and emotional due to human centric lightingof the present invention. As shown in FIG. 1a , starting the intelligenthuman centric lighting system 100 is in an environment where variousadjustable lighting modules have been configured (e.g., a test space),and provides light signal lighting parameters such as spectrum, lightintensity, flicker rate and color temperature that can be changed. Fordifferent target emotions, the present invention uses the fMRIcompatible image interaction platform 110 formed by the fMRI system toguide the emotion of voice and image, and at the same time, it ismatched with a specific effective spectrum to stimulate for 40 seconds.Observe the changes in the area where the blood oxygen-level changes inthe tester's brain to verify whether the “effective color temperature”can significantly induce the tester's emotional response, and thedetails are as follows.

Next, please refer to FIG. 1b and FIG. 1c , wherein FIG. 1b is a flowchart of collecting original data of human centric lighting tophysiological and emotional responses according to the presentinvention, and FIG. 1c is a judging flow of human centric lighting tospecific physiological and emotional responses. As shown in step 1100 inFIG. 1b , each tester has been positioned on the compatible imageinteraction platform 110, and then each tester is guided to stimulatevarious emotions through known pictures. Afterwards, as shown in step1200, the BOLD response in the brain of the tester's various emotionsafter being stimulated by the picture is recorded through the compatibleimage interaction platform 110. Next, as shown in step 1300, the testeris visually stimulated by irradiating light to provide spectrums withdifferent color temperature parameters. for example, use LED lamps withelectronic dimmers to provide spectrums with different color temperatureparameters. In the embodiment of the present invention, nine groups ofvisual stimuli with different color temperatures, including 2,700 K,3,000 K, 3,500 K, 4,000 K, 4,500 K, 5,000 K, 5,500 K, 6,000 K, and 6,500K, are provided. Among them, after completing 40 seconds of effectivelight irradiation and stimulation each time, you can choose to givetesters one minute of invalid light source lighting (full spectrumnon-flicker white light) to achieve the purpose of emotional relaxation.Further, it is also possible to choose to give the tester a 40 secondcounter effect light stimulation to observe whether the response in thearea that responded to the original effective light stimulationdecreased. In the embodiment of the present invention, after thecompatible image interaction platform 110 has recorded the BOLD responsein the brain of the tester's specific emotion after being stimulated bythe picture, the tester is visually inspected by providing spectra withdifferent color temperature parameters. The stimulus, as shown in step1310 in FIG. 1c , is used to provide a spectrum with a color temperatureof 3,000 K, then, as shown in step 1320, to provide a spectrum with acolor temperature of 4,000 K, and finally, as shown in step 1330, toprovide a color temperature for the 5,700 K spectrum, the test subjectswere visually stimulated.

Next, as shown in step 1400, the BOLD response of the test subject'sbrain after being stimulated by light is recorded through the compatibleimage interaction platform 110. In the embodiment of the presentinvention, after the tester is stimulated by lighting with differentcolor temperature parameters, the compatible image interaction platform110 records the BOLD response results with emotional response areas inthe corresponding limbic system of the tester in sequence. Among them,the location of limbic system triggered by different emotions isdifferent, and the above limbic system with emotional response in brainarea is shown in Table 1 below.

TABLE 1 Limbic system Function ACC Emotion Cuneus Vision, Controlbipolar disorder Cerebellum Balance, Coordination, Antidepressant &Anxiety Insula Lobe Affection, addiction Lingual Gyrus Logic, Vision{grave over ( )} Antidepressant & Anxiety Rolandic Operculum EmotionManagement, Gustatory Sense Superior Frontal Gyrus Working Memory,Self-consciousness, laugh Middle Temporal Gyrus Emotion Recognition,Creativity MCC Emotion Pallidum Affection, Motion, Cognition, RewardSystem Temporal Pole Affection, Language, Auditory

The compatible image interaction platform 110 records the responseresult of BOLD in a specific area of the brain, and the response resultis judged by calculating the area of these emotional response parts whenthe brain area has more limbic system with BOLD emotional response, forexample, when there is a BOLD emotional response The larger the area ofemotional response, the stronger the response to a specificphysiological and emotional. In the embodiment of the present invention,as shown in step 1410 in FIG. 1c , it is used to record the reactionresult of BOLD with a color temperature of 3,000 K after spectralirradiation, and then, as shown in step 1420, it is used to record thecolor temperature of 4,000 K. Finally, as shown in step 1430, thereaction result of BOLD after spectral irradiation is used to record thereaction result of BOLD after spectral irradiation with a colortemperature of 5,700 K. Among them, after the tester passes through thelighting procedure after the excitement is induced, the compatible imageinteraction platform 110 records the response results of BOLD in aspecific area of the brain as shown in Table 2.

TABLE 2 Excitement Index Limbic system 3,000K 4,000K 5,700K ACC 0 0 −30Cerebellum 577 0 −75 Middle Temporal Gyrus 0 99 0 Superior Frontal Gyrus0 127 0 Total T Score 577 226 −105

Among them, after the tester passes through the lighting procedureinduced by happiness, the compatible image interaction platform 110records the response results of BOLD in a specific area of the brain asshown in Table 3.

TABLE 3 Happiness Index Limbic system 3,000K 4,000K 5,700K ACC 0 0 −162Cerebellum 163 252 0 Pallidum 80 0 0 Insula Lobe 85 307 0 Lingual Gyrus0 58 403 Temporal Pole 0 57 0 Total T Score 328 674 241

Among them, after the tester passes through the lighting procedure afterthe emotion-induced amusement, the compatible image interaction platform110 records the response results of BOLD in a specific area of the brainas shown in Table 4.

TABLE 4 Amusement Index Limbic system of brain 3,000K 4,000K 5,700KLingual Gyrus 0 279 327 Cerebellum 539 215 226 Middle Temporal Gyrus 0 090 MCC −83 32 0 Total T Score 456 526 643

Afterwards, as shown in step 1500, the results of the BOLD reaction thata specific color temperature can increase a specific emotion arescreened by lighting, and the specific color temperature is called an“effective color temperature”. In this embodiment, the BOLD responseresult of the emotional response area in the limbic system of thetester's corresponding brain is recorded, so as to summarize thestimulation effect of color temperature on the brain, as shown in Tables1 to 3 shown, for the BOLD brain region-dependent response results thatscreened out the specific color temperature that can increase a specificemotion, we calculated those specific color temperature that can makethe response effect of a specific emotion reach the maximum responsevalue (that is, the maximum response area value with BOLD).

As shown in step 1510, when the tester has recorded the excitationemotion on the compatible image interaction platform 110 and finishesthe lighting program again, the maximum response value is calculated.For example, according to the records in Table 2, the total score of3,000 K (577) is subtracted from the total score of 4,000 K (226) toobtain 351. Then, after subtracting the total score (−105) of 5,700 kfrom the total score (577) of 3,000 K, 682 is obtained. The total scoreof response value under 3,000 K lighting after excitation is 1033.

Next, as shown in step 1520 in FIG. 1c , when the tester has recordedthe excitation emotion on the compatible image interaction platform 110and completed the lighting program again, it starts to calculate themaximum response value. For example, according to the records in Table2, subtract the total score (226) of 4,000 K from the total score (577)of 3,000 K to obtain −351. Then, after subtracting the total score(−105) of 5700 k from the total score (266) of 4,000 K, 371 is obtained.

Then, as shown in step 1530 in FIG. 1c , after the tester has recordedthe excitation emotion induction on the compatible image interactionplatform 110 and completed the lighting program, it starts to calculatethe maximum response value. For example, according to the records inTable 2, after subtracting the total score (−105) of 5,700 K from thetotal score (577) of 3,000 K, it obtains −682. Then, the total score(−105) of 5,700 K is subtracted from the total score (−105) of 4,000 Kto obtain 371.

According to the above calculation, after the excitation emotion isinduced, the excitation emotion can reach the maximum response value at3,000 K lighting. That is, 3,000 K illuminance can make excitement get amore obvious additive effect (that is, compared with the totalcalculated score of 4,000 K and 5,700 K illuminance, the totalcalculated score of 3,000 K illuminance is 1033, the highest).Therefore, 3,000 K illuminance is used as the “effective colortemperature” of excitement. For other emotions, such as “effective colortemperature” of happiness and amusement, different “effective colortemperatures” can be obtained from the above calculation results insteps 1510 to 1530, as shown in Table 5 below.

TABLE 5 Emotion Effective Color Temperature Excitement 3,000K Happiness4,000K Amusement 5,700K

Next, according to the statistical results in Table 5, the effectivecolor temperature can be regarded as the result of a specificphysiological and emotional-dependent response, and this effective colortemperature can be regarded as the “enhanced spectrum” of the “bloodoxygen-level dependence” of fMRI on a certain emotion. For example, aneffective color temperature of 3,000 K can represent the “enhancedspectrum” of the fMRI system in “excited” emotions. For example, aneffective color temperature of 4,000 K can represent the “enhancedspectrum” of the fMRI system in “happy” emotions. For example, theeffective color temperature of 5,700 K can represent the “enhancedspectrum” of the fMRI system in “amusement” emotions.

Finally, as shown in step 1600, an “enhanced spectrum” databasecorresponding to the effect of a particular emotion can be establishedin the fMRI system. The tester is stimulated by the above-mentionedhuman centric lighting parameters, and the BOLD response of the tester'sbrain when the tester's brain is stimulated by light is observed andrecorded through the fMRI system. The additive and multiplicativeresponse of “blood oxygen-level dependence increase” makes a specificeffective color temperature can be regarded as the “enhanced spectrum”of the “blood oxygen-level dependence” of fMRI for a specific emotion.Obviously, the present invention objectively deduces the tester's“enhanced spectrum” under a specific physiological and emotionalresponse based on the statistical result of the BOLD reaching a specificemotional response at a specific “effective color temperature” in Table5, and This “enhanced spectrum” is used as the evidence of the mostsynergistic physiological and emotional response to a specific emotion.(Including: excitement, happiness, amusement, anger, disgust, fear,sadness, calm, or neutrality)

It should be emphasized that, in the entire implementation process ofFIG. 1b and FIG. 1c , the statistical results in Table 5 are obtainedafter 100 testers are respectively subjected to a complete test ofmultiple specific emotions. For example, in terms of excitement,providing an effective color temperature of 3,000 K as the “enhancedspectrum” under the excited physiological and emotional response canmake the tester's excited emotions produce the most synergisticphysiological-emotional response. For example, in terms of happyemotions, providing an effective color temperature of 4,000 K as the“enhanced spectrum” under the happy physiological and emotional responsecan make the tester's happy emotions produce physiological and emotionalresponses with the strongest synergistic effect. Another example, interms of amusement emotions, providing an effective color temperature of5,700 K as an “enhanced spectrum” under the amusement physiological andemotional response can make the tester's amusement emotions produce aphysiological and emotional response with the strongest synergisticeffect.

In addition, it should also be emphasized that the above-mentioned threecolor temperatures are only representative of the embodiments of thepresent invention, and not only the lighting of the three colortemperatures is used as the “enhanced spectrum” under the threephysiological and emotional responses. In fact, the whole process ofFIG. 1b and FIG. 1c can be carried out for different emotions (includingexcitement, happiness, amusement, anger, disgust, fear, sadness, calm orneutral) after 2,000 K color temperature is increased by 100 K as aninterval. Therefore, Table 5 of the present invention is only the resultof the disclosure part, not to limit the present invention. Theinvention is only limited to these three embodiments.

Next, the present invention is to establish an artificial intelligencemodel of “the correlation between brainwaves and brain images of generalphysiological and emotional”, so that in future commercial promotion,the results of other sensing devices can be directly used to inferphysiological and emotional without using fMRI system. Among them, thesensing device matched with the present invention includeselectroencephalograph (EEG). In the following embodiments, theelectroencephalograph 130 is used to establish the human centricphysiological and emotional response to light, and the eye tracker 150or the expression recognition technology auxiliary program 170 can beused to replace the fMRI system's response to physiological andemotional. However, the eye tracker 150 or the expression recognitiontechnology auxiliary program 170 will not be disclosed in the presentinvention, but will be announced first.

Please refer to FIG. 2a , which is a method for establishing a humancentric lighting electroencephalogram response to physiological andemotional according to the present invention. As shown in FIG. 2a , thepresent invention is a method for establishing the human centriclighting response to physiological and emotional through theelectroencephalograph 130, including: first, as shown in step 2100, the“enhanced spectrum” database information in Table 5 is also stored inthe memory of the electroencephalograph 130. Next, as shown in step2200, let the testers wear the EEG, and guide each tester to stimulatevarious emotions through the elements of known pictures or videos.Afterwards, as shown in step 2300, the intelligent human centriclighting system 100 is activated, and light signal parameters such asspectrum, light intensity, flicker rate, and color temperature that canbe changed are provided to stimulate the tester with light. Next, theelectroencephalogram file after being illuminated with different colortemperatures under a specific emotion is recorded by theelectroencephalograph 130. For example, in this embodiment, each testeris first stimulated with excitement, and then, in steps 2310 to 2330,different color temperatures of 3,000 K, 4,000 K and 5,700 K areprovided to stimulate the tester respectively, and the tester isrecorded in when stimulated by excitement, the electroencephalogram fileof the specific emotion after the tester is illuminated with differentcolor temperatures is stored in the device in the memory of theelectroencephalograph 130. In the embodiment of the present invention,the electroencephalogram files after 100 testers have completed specificemotional stimulation and lighting have been recorded respectively,therefore, a larger memory is required.

Next, as shown in step 2400, the electroencephalogram files of specificemotions (e.g., excitement, happiness, amusement) stored in the memoryof the electroencephalograph 130 is learned through the learning methodof artificial intelligence. Since the electroencephalograph 130 can onlystore the waveform of the electroencephalogram, the electroencephalogramcurrently stored in the memory of the electroencephalograph 130 is theelectroencephalogram file after a known specific triggering emotionalstimulus and lighting of different color temperatures. It should benoted that, in the actual test, different testers have differentelectroencephalogram files for the same emotional stimulus and lightingwith the same color temperature. Therefore, during the learning processof step 2400, the present invention needs to classify theelectroencephalogram files of specific emotions through the informationof the “enhanced spectrum” database. Group the electroencephalogramfiles with a color temperature of 3,000 K, for example, For theelectroencephalogram files of happy emotions, only group theelectroencephalogram files of different testers with a color temperatureof 4,000 K. Another example, for the electroencephalogram file of happymood, only the electroencephalogram files of different testers at 4,000K color temperature are grouped; for example, for theelectroencephalogram file of happy mood, only the electroencephalogramfiles of different testers at 5,700 k color temperature are grouped.Then, the EEG is trained through machine learning in artificialintelligence. In the embodiment of the present invention, in particular,a transfer learning model is selected for learning and training.

In the process of learning and training using the transfer learningmodel in step 2400, the group of electroencephalogram files for specificemotions is learned and trained by counting, calculating and comparingthe similarity. For example, when learning and training the group ofelectroencephalogram files with 3,000 K color temperature, it is basedon statistics, calculation and comparison of the ranking of the highestsimilarity and the lowest similarity among the electroencephalogramfiles with 3,000 K color temperature. for example, the ranking with thehighest similarity can be regarded as the electroencephalogram file withthe strongest emotion, the ranking with the lowest similarity can beregarded as the electroencephalogram file with the weakest emotion, andthe electroencephalogram file with the strongest emotion can be regardedas the electroencephalogram file. As the “target value”, theelectroencephalogram file with the weakest emotion ranking is used asthe “starting value”. For the convenience of explanation, the mostsimilar at least one electroencephalogram file is taken as the “targetvalue”, and the least similar at least one electroencephalogram file istaken as the “start value”, and different scores are given, for example,“target value” is given 90 points for similarity, and 30 points for“initial value”. Similarly, complete the electroencephalogram files ofthe series of happy emotions in the 4,000 K color temperature category,and the electroencephalogram files of the series of the surprisedemotions in the 5,700 K color temperature category. Among them, the“start value” and “target value” can be formed into a score interval ofsimilarity.

Afterwards, as shown in step 2500, an electroencephalogramclassification and grading database in artificial intelligence (it maybe referred to as an artificial intelligence electroencephalogram filedatabase) is established. After the step 2400 is passed, theclassification results of the “target value” score and the “start value”score are given to the electroencephalogram file groups of variousspecific color temperatures to form a database, which is stored in thememory of the electroencephalograph 130. The purpose of establishing theelectroencephalogram classification and grading database in step 2500 ofthe present invention is to obtain the electroencephalogram file of theunknown tester after receiving a specific emotional stimulus and givinglighting of a specific color temperature to an unknown tester. After thesimilarity score interval between the electroencephalogram file of theunknown tester and the electroencephalogram file in the database iscompared, it can be used to judge or infer the current state of theunknown tester's hyperemia reaction in the brain. The detailed processis shown in FIG. 2 b.

Next, please refer to FIG. 2b , which is a lighting database forconstructing a user's effective human centric lighting according to thepresent invention. First, as shown in step 3100, the tester is put onthe electroencephalograph 130, and the tester is allowed to watch apicture evoked by a specific emotion. Afterwards, as shown in step 3200,the intelligent human centric lighting system 100 is activated bymanagement control module 611 (as shown in FIG. 3) in an environment(e.g., a test space) that has been configured with various adjustablemultispectral lighting modules. To provide light parameters such asspectrum, light intensity, flashing rate, color temperature and otherlight signal light parameters that can be changed. Next, as shown instep 3300, obtain the electroencephalogram file of the tester after theinduced emotion and lighting, and store it in the memory module 617 ofthe cloud 610 (as shown in FIG. 3). Next, as shown in step 3400, importthe artificial intelligence electroencephalogram file database into themanagement control module 611. Wherein, the management control module611 will set a score of whether the similarity is sufficient. Forexample, when the similarity score is set to be more than 75 points, itmeans that the tester's brain hyperemia reaction is sufficient. Next, asshown in step 3500, in the management control module 611, the similaritybetween the tester's electroencephalogram file and the artificialintelligence electroencephalogram file is compared. for example, whenthe similarity score of the tester's electroencephalogram files aftercomparison is 90 points, the management control module 611 immediatelyjudges that the tester's brain hyperemia reaction is very sufficient, soit will go to step 3600 to terminate the person with a specific emotionDue to lighting test. Next, go to step 3700, record the human centriclighting parameters in the tester's brain when the hyperemia responsehas reached the stimulus, into a database and store in the memory module617.

Next, in the procedure of step 3500 in FIG. 2b , if the similarity scoreafter the comparison between the tester's electroencephalogram file andthe artificial intelligence electroencephalogram file is 35 points, themanagement control module 611 will determine the tester's brain If thehyperemia reaction is insufficient, step 3800 will be performed, and themanagement control module 611 will continue to strengthen the humancentric lighting test, including: according to the similarity score, themanagement control module 611 can control it to provide an appropriateincrease in the lighting time or increase light intensity. Then, theelectroencephalogram file after increasing the illumination time orintensity is obtained again through step 3300. After step 3400, thehuman centric lighting test is not stopped until the similarity scorereaches the set similarity score of more than 75 points. Wherein, whenthe management control module 611 determines that the hyperemia reactionin the tester's brain has reached the stimulation, in step 3700, a datafile of the human centric lighting parameters of the tester is created.Finally, the management control module 611 will form a “human centriclighting parameter database” of the human centric lighting parameters ofeach tester and store it in the memory module 617. Obviously, when thereare more testers, the artificial intelligence electroencephalogram filedatabase of the present invention will learn more electroencephalogramfiles, so that the similarity score of the present invention is more andmore accurate.

After the artificial intelligence model of the “human centric lightingparameter database” is established, after the intelligent human centriclighting system 100 is activated, the present invention can deduce theresult only by observing the electroencephalogram file of theelectroencephalograph 130, that is, it can be deduced The physiologicaland emotional changes in the brain images of the new test subjects canbe inferred based on the artificial intelligence model of the “HumanCentric Lighting Parameter Database” without using a high-value fMRIsystem. So that the intelligent human centric lighting system 100 can bepromoted and used commercially. In addition, in order to enable the“human centric lighting parameter database” to be used commercially, the“human centric lighting parameter database” may be further stored in theinternal private cloud 6151 in the cloud 610.

Next, please refer to FIG. 3, which is a system architecture diagram ofthe intelligent human centric lighting system 100 of the presentinvention. As shown in FIG. 3, the overall architecture of theintelligent human centric lighting system 100 of the present inventioncan be divided into three blocks, including: a cloud 610, a lightingfield terminal 620 and a client terminal 630. The internet is used as aconnection channel, so the three blocks can be distributed in differentareas, and of course they can be configured together. The cloud 610further includes: a management control module 611, which is used forcloud computing, cloud environment construction, cloud management or useof cloud computing resources, etc., and also allows users to access,construct or modify the content in each module through the managementcontrol module 611. The consumption module 613 is connected with themanagement control module 611 and is used as a cloud service subscribedand consumed by the user. Therefore, the consumption module 613 canaccess various modules in the cloud 610. The cloud environment module615, connected with the management control module 611 and theconsumption module 613, divides the cloud background environment into aninternal private cloud 6151, an external private cloud 6153, and apublic cloud 6155 (for example, a commercial cloud), etc., and canprovide system providers or an interface to a user's external orinternal service. The memory module 617 is connected to the managementcontrol module 611 and is used as a storage area of the cloudbackground. The technical contents required to be executed by eachmodule in the present invention will be described in detail in thesubsequent different embodiments. The lighting field terminal 620 cancommunicate with the cloud 610 or the client terminal 630 through theinternet. The lighting field terminal 620 is provided with a LED lampsgroup 621 composed of a plurality of light-emitting devices. And theclient terminal 630 can communicate with the cloud 610 or the lightingfield terminal 620 through the internet. Among them, the client terminal630 of the present invention includes general users and editors who usethe intelligent human centric lighting system 100 of the presentinvention for various commercial operations, all of which belong to theclient terminal 630 of the present invention, and the representativedevice of the client terminal 630 or the device can be a fixed devicewith computing function or a portable intelligent communication device.In the following description, the user, creator, editor or portablecommunication device can all represent the client terminal 630. Inaddition, in the present invention, the above-mentioned internet may bean Artificial Intelligence of Things (AIoT).

Please refer to FIG. 4, which is a method for constructing lightenvironment platform 400 according to the present invention. In theprocess of FIG. 4, the process is performed in the system of theintelligent human centric lighting system 100 in FIG. 3, wherein theintelligent human centric lighting system 100 has a plurality of LEDlamps group 621 providing different spectrums. In particular, thepresent invention should illustrate that the LED lamps group canselectively modulate the voltage or current of the individual LEDlighting to combine a multispectral combination with a specific colortemperature, so as to provide a multispectral combination for lighting.Of course, the present invention can also choose to use a plurality ofLED lamps with a specific luminous spectrum, by providing a fixedvoltage or current to make each LED lamps that is energized emit itsspecific spectrum to combine a multispectral combination with a specificcolor temperature come to light. In addition, it should be emphasizedthat the LED lamps group 621 with different spectrums in the presentinvention need to emit different spectrums through a plurality of LEDlamps group 621 according to the actual lighting process. Therefore, theLED lamps group 621 with different spectrums can be composed ofdifferent. The spectrum of light-emitting devices can also be composedof multiple identical light-emitting devices, and the spectrum emittedby the light-emitting devices can be modulated into different spectrumsby controlling the power provided by the device. Therefore, the presentinvention does not limit the embodiments of the above LED lamps group621 with different spectrums, and of course also includes light-emittingdevices with different spectrums formed by other means.

First, as shown in step 410, a multispectral light emitting device clouddatabase is constructed. The “human centric lighting parameter database”stored in the memory module 617 or stored in the internal private cloud6151 is loaded into the management control module 611 by the managementcontrol module 611 in the cloud 610. Among them, the “human centriclighting parameter database” stored in the cloud 610 already knows thatvarious color temperatures can make people (or users) get correspondingemotional stimulation. for example, a specific color temperature canmake a specific emotion have a stimulating effect of a multiplicativeresponse.

Next, as shown in step 411, a cloud database of light scenes of themultispectral lighting device is to be constructed. Since each colortemperature can be combined by different multiple spectrums, that is tosay, the same color temperature can be combined by different multiplespectrums. For example, when we want to build a spectrum that canprovide 4,000 K color temperature, we can choose the multispectralcombination of Maldives at 4,000 K color temperature, or we can choosethe multispectral combination of 4,000 K color temperature in Bali,Indonesia, or further choose Monaco Beach at 4,000 K multispectralcombination of color temperature. Obviously, these multispectralcombinations with a color temperature of 4,000 K have differentmultispectral combinations according to their geographical location(including latitude and longitude), time/brightness/flashing rate andother factors. Therefore, in step 411, according to the relationshipbetween the color temperature and the corresponding emotions in the“human centric lighting parameter database”, the cloud 610 can collectdifferent multispectral combinations of specific color temperatures indifferent geographical locations on the earth, for example, collectingon the earth different multispectral combinations at 4,000 K colortemperature in different geographic locations (e.g., 4,000 K colortemperature at different latitude and longitude), or collect differentmultispectral combinations at 4,000 K color temperature at differenttimes on earth (e.g., 4,000 K color temperature at 9:00 am). Afterwards,the collected different multispectral combinations of differentgeographic locations on the earth at specific color temperatures arealso stored in the memory module 617. Through the control of themanagement control module 611 in the intelligent human centric lightingsystem 100, the parameters of various multispectral combinations withspecific color temperature (i.e., time at different geographicallocations or locations) can be adjusted by controlling a plurality ofLED lamps group 621 with different spectra, which are stored in thememory module 617. The intelligent human centric lighting system 100 ofthe present invention can construct a “cloud database of multispectrallight-emitting devices” with multispectral combinations of various colortemperatures formed in different geographical locations. Obviously, the“multispectral light emitting device cloud database” constructed in step411 is the result of adjustment by multiple LED lamps group 621 withdifferent spectra. In addition, it should be emphasized that aftermastering the stimulation effect that different specific colortemperatures can make specific emotions have additive reaction, whenforming the multispectral combination of various color temperatures, inaddition to the multispectral combination according to differentgeographical locations on the earth, the present invention can alsoconsider different longitude and latitude/time/brightness/flicker rateand other factors through artificial intelligence, The invention doesnot limit the synthesis or combination of multispectral combinationsdifferent from the actual geographical location. Obviously, in step 411,the present invention has constructed a light scene database withmultispectral light emitting device cloud database. Therefore, accordingto the constructed database of different light scenes, the intelligenthuman centric lighting system 100 can provide multispectral lightingservices under different color temperatures through the multispectrallighting device. At this time, the “multispectral light emitting devicecloud database” constructed in step 411 can be stored in the memorymodule 617 or in the internal private cloud 6151 or in the public cloud6155 (e.g., commercial cloud).

As shown in step 430, it is determined whether the lighting of themultispectral combination is effective. Since different users may havedifferent effects on emotional stimulation or influence through thespectrum of human centric lighting, it is necessary to adjust thelighting spectrum of the multispectral combination. Next, when theclient terminal 630 enters the intelligent human centric lighting system100 of the present invention, he can go through the management controlmodule 611 to the memory module 617 or the “multispectral light emittingdevice cloud database” in the internal private cloud 6151 or the publiccloud 6155, select the emotion you want to achieve. After that, themanagement control module 611 can go to the memory module 617 or the“multispectral light emitting device cloud database” in the internalprivate cloud 6151 or the public cloud 6155, select a defaultmultispectral combination, and control multiple different spectrums TheLED lamps group 621 is used to adjust the multispectral combination ofthe desired mood, and let the adjusted multispectral combination performa lighting program for the user. For example, when the user wants toadjust the mood to happiness or amusement, according to the “humancentric lighting parameter database”, the user can choose to use thecolor temperature of 4,000 K to illuminate. At this time, the user cango to the default multispectral combination provided by the“multispectral light emitting device cloud database”, or the user canchoose a multispectral combination that can provide the colortemperature of 4,000 K, of course, the user can also choose a specificmultispectral combination used by the most people for irradiation. Atthis time, when the user uses the multi spectral combination provided bythe intelligent human centric lighting system 100 in the “multispectrallight emitting device cloud database”, the present invention is calledthe default multispectral combination.

Next, as shown in step 430, when the user selects a multispectralcombination preset as happiness or amusement (for example, the systemdefaults to the multispectral combination of Maldives at 4,000 K colortemperature), and carries out the lighting program through themultispectral combination adjusted by a plurality of LED lamps group 621with different spectra, for example, after 15 minutes of lightingprogram, The user can judge or evaluate whether the multispectralcombination of irradiation has effectively achieved happiness orpleasant emotion. Among them, the way for users to judge or evaluatewhether they have effectively achieved happiness or amusement emotionscan be determined according to their own feelings.

Continuing as shown in step 430, when the user intuitively feels that heor she has effectively achieved a happy or amusement mood, the userexperience can be recorded and stored in the external private cloud 6153or the public cloud 6155, for example, after the record of useexperience is stored in the external private cloud 6153, it can be usedas the user's own use experience file. For example, of course, the useexperience can also be recorded and stored in the public cloud 6155 toprovide reference for other users. If the user does not feel happy oramusement after 15 minutes of lighting, the user can adjust themultispectral combined spectral recipe through the management controlmodule 611, for example, adjust the lighting time to 30 minutes, orreplace for a multispectral combination light scene, for example, goback to step 411 to reselect another multispectral combination lightscene, and replace the multispectral combination light scene from thedefault Maldives to Bali, Indonesia. After that, in step 430, themultispectral lighting procedure is performed again for 15 minutes, andafter the lighting procedure is completed, it is judged or evaluatedagain whether the lighting of Bali's multispectral combination haseffectively achieved a happy or amusement. Until the user feels thatafter the multispectral lighting of the current light scene, the happyor amusement mood has been effectively achieved, the effective lightscene use experience can be recorded and stored to form a “spectralrecipe”, and finally, and store this “spectral recipe” in the externalprivate cloud 6153 or the public cloud 6155 to form a shared platform.Obviously, there are multiple “spectral recipe” stored in the sharedplatform. The contents stored in the shared platform include: thelighting control parameters of the light scene in which the userachieves the specific emotional effect and the multispectral combinationof the LED lamps group 621 with multiple different spectra generatingthe specific emotional light scene (hereinafter referred to as thelighting parameters).

Finally, as shown in step 470, a light environment platform isconstructed. After the user records and stores the effective useexperience in the external private cloud 6153 or public cloud 6155, inaddition to being the user's own use experience file, the intelligenthuman centric lighting system 100 can record and store the effectiveexperience data of many users in the internal private cloud 6151 orpublic cloud 6155 after massive data analysis in step 470, Theinformation stored in the public cloud 6155 forms a “sharing platform”of the optical environment. For example, the intelligent human centriclighting system 100 can analyze the massive data of many users'experience data, and then can obtain the ranking of the “spectralrecipe” of different light scenes with specific color temperatureselected by the user. This ranking can provide a reference for the userto select the “spectral recipe”. Further, after analyzing these massivedata, we can get different indicators to provide users with reference.For example, in terms of different multispectral combinations of 4,000 Kcolor temperature, different usage orders can be made according to theuser's gender, age, race, season, time, etc., so that the lightenvironment platform constructed by the present invention can be used asother designers who are interested or willing to provide human centricspectral recipe, use these indicators for commercial services andoperations. Therefore, the light environment platform constructed by thepresent invention can allow the intelligent human centric lightingsystem 100 to provide various usage experiences after curation oralgorithm operation as the default multispectral combination. Inaddition, users can also choose a “spectral recipe” that is mostselected by the user for lighting according to the user experience dataafter calculation.

In the embodiment of FIG. 4, step 450 can exist selectively. Forexample, if the user only establishes the database for user's own use,user can directly record and store the effective use experience in theexternal private cloud 6153 or public cloud 6155 after determining thatit is valid in step 430 without this step 450. The database of the“spectral recipe” construction service to be constructed in step 450will be described in the following embodiments.

Next, in FIG. 4, there is another embodiment that can be used forcommercial services and operations, it can provide an authoring platformthat allows different users or creators to create new “spectral recipe”through this authoring platform. As shown in step 460, a “spectralrecipe” authoring platform is provided in the intelligent human centriclighting system 100. The client terminal 630 using this “spectralrecipe” authoring platform can be distributed all over the world and cancommunicate with each other through the internet. The “light environmentplatform” connection in the cloud 610 of the present invention.Obviously, the present invention defines a “spectral recipe” creationplatform here, that is, a “spectral recipe” creation platform means thata user or client terminal 630 can connect to the public cloud 6155 inthe cloud 610 or a “sharing platform” through the internet, so thatusers or client terminal 630 can use the “spectral recipe” informationon the public cloud 6155 or “sharing platform” for editing work.Therefore, after the user or client terminal 630 obtains variouscalculated usage experience data from the “sharing platform”, the useror client terminal 630 can obtain the experience data based on theuser's gender, age, race, season, time, etc., edit or create by clientterminal 630 to construct an edited “spectral recipe” of multi-scene ormulti-emotional multispectral combination.

Firstly, the first embodiment of the present invention uses the“spectral recipe” creation platform for commercial service andoperation. For example, for the emotional stimulation result of 4,000 Kcolor temperature, the user or client terminal 630 can combine differentlight scenes through the “spectral recipe” creation platform. Forexample, the first paragraph of client terminal 630 selects the multispectra combination of Maldives, the second paragraph is to choose themultispectral combination of Bali, and finally, the third paragraph endswith the multispectral combination on the beach of Monaco. In this way,after each segment is matched or configured with the spectralirradiation time, a new spectral combination of the multi-light scenecan be formed. Finally, the spectral combination of the multi-lightscene can be stored in the “sharing platform”, which can provide otherusers with options. The spectral combination of this multi-light sceneserves as the “spectral recipe” for its emotional adjustment. Amongthem, the creation platform of the present invention can also select aspecific color temperature at a specific time, for example, when a userwants to perform emotional stimulation at 9:00 am, the user can furtherselect the aforementioned three multispectral combinations at 9:00 am.Further, the multispectral irradiation time of each segment can beconfigured to be the same or different, for example, each segment isirradiated for 15 minutes. The first stage and the third stage may bearranged for 15 minutes, and the second stage may be arranged andirradiated for 30 minutes, and these same or different timeconfigurations can be selected by the user.

Secondly, in the second embodiment of the present invention using the“spectral recipe” creation platform, different color temperatures (thatis, multiple emotions) can be combined to achieve specific emotionalstimulation results through lighting with multiple emotions, forexample, the client terminal 630 can use the “spectral recipe” creationplatform to combine multiple emotions. for example, the first paragraphof the client terminal 630 is to select a multispectral combination of4,000 K (happy emotion), and the second paragraph is to select 3,000 K(excited emotion). Finally, the third paragraph ends with amultispectral combination of 5,700 K (amusement emotion). In this way,after each segment is matched or configured with multispectralirradiation time, a new multi-emotional multispectral combination can beformed. Finally, this multi-emotional multispectral combination can bestored in the “sharing platform”, which can provide users with choices.This multispectral combination of multiple emotions serves as the“spectral recipe” for its emotional adjustment. Similarly, the creationplatform in this embodiment can also select a specific color temperatureat a specific time. For example, when the user wants to performemotional stimulation at 9:00 am, user can further select the abovethree paragraphs spectral combination at 9:00 am. Further, themultispectral irradiation time of each segment can be configured to bethe same or different, for example, each segment is irradiated for 15minutes. The first stage and the third stage may be arranged for 15minutes, and the second stage may be arranged and irradiated for 30minutes, and these same or different time configurations can be selectedby the user.

Next, it should be further explained that after the editing or creationof the above-mentioned first embodiment (multispectral combination ofmulti-light scenes) and the second embodiment (multispectral combinationof multi-mood light scenes) is completed, step 430 also needs to gothrough step 430. Process to step 470. For example, step 411 should bepassed first, and the illumination should be performed through themulti-spectrum adjusted by a plurality of LED lamps group 621 withdifferent spectra. Next, after step 430, it is determined whether thecombination of the above-mentioned “spectral recipe” achieves the effectthat the creator wants, including: the spectral combination of themulti-light scene of the first embodiment and the irradiation time ofthe corresponding configuration, and the second embodiment themulti-emotional spectral combinations and configured exposure times. Ifthe effect set by the creator can be achieved, the control parameters ofthe LED lamps group 621 required to construct these “spectral recipe”can be formed into a database that can provide a “spectral recipe”construction service, as shown in step 450. Then, as shown in step 470,after uploading the database of the “spectral recipe” constructionservice constructed in step 450 to the cloud, these “spectral recipe”can be added to the public cloud 6155 of the present invention to form alight environment platform. If after step 430, it is determined that acertain “spectral recipe” cannot achieve the effect set by the creator,then you can go back to step 411 to adjust the irradiation time of eachsegment, or change to a different light scene combination (the firstembodiment) or change different emotional combinations (the secondembodiment), until these “spectral recipe” can achieve the effect set bythe creator, then the process from step 430 to step 470 can be used tojudge that these are effective. The “spectral recipe” of the lightenvironment is added to the public cloud 6155 of the present inventionto form a light environment platform.

In addition, in order to make the multi-scene combination ormulti-emotion combination of the “spectral recipe” creation platformeffective, it may be necessary to go through a specific LED lamps group621 or a specific configuration diagram to achieve the best effect.Therefore, the present invention is further configured with a databaseof hardware services, as shown in step 420, and further configured witha database of software services, as shown in step 440. Among them, thedatabase of hardware services and the database of software services arealso embedded with some management information when building “spectralrecipe”, including installation or delivery of hardware devices, orincluding providing and building these “spectral recipe” through thedatabase of software services software services such as space design,scene planning, or interface setting required by spectral recipe. Inaddition, the database of the hardware service and the database of thesoftware service may be configured at one end of the client terminal630, or may be configured in the cloud 610, which is not limited in thepresent invention. Obviously, in the embodiment of FIG. 4, the presentinvention has provided the process of constructing various “spectralrecipe” and the database of “spectral recipe” construction services, aswell as the hardware services required for the construction of “spectralrecipe”. The database and software service database have beenestablished in the light environment platform. It should be noted thatthe “sharing platform” finally established in step 470 is a “spectralrecipe” that can provide effective spectral combinations of multi-lightscenes and multi-emotional light scenes. “Sharing Platform” providesvarious commercial services and operations.

Next, please refer to FIG. 3 and FIG. 5a , FIG. 5a is an automaticallyadjustable intelligent human centric lighting method 500 of the presentinvention. First, as shown in step 510, the management control module611 loads the “human centric lighting parameter database” stored in thememory module 617 into the management control module 611. Among them,the “human centric lighting parameter database” stored in the memorymodule 617 already knows that various color temperatures can give people(or users) corresponding emotional stimulation. For example, a specificcolor temperature can make a specific emotion have the stimulatingeffect of additive reaction.

Next, as shown in step 530, a cloud data database of multispectralrecipe for human centric lighting is constructed. In step 530, the“spectral recipe” stored in the “sharing platform” established in step470 can be downloaded by the management control module 611 as a clouddata database source for constructing a multispectral recipe with humancentric lighting in the present invention. Therefore, the process offorming the “spectral recipe” established in step 470 will not bedescribed in detail, please refer to the detailed description of step470.

Next, as shown in step 520, a “situational dynamic spectrum editingplatform” is provided. Similarly, the present invention defines a“situational dynamic spectrum editing platform” here, which is similarto the aforementioned “spectral recipe creation platform”. The clientterminal 630 can connect to the public cloud 6155 or “sharing platform”in the cloud 610 via the internet, so that the user or client terminal630 can use the “spectral recipe” information on the public cloud 6155or “sharing platform” for situational editing work. After the“situational dynamic spectral editing platform” obtains a variety of“spectral recipe” data from the “sharing platform”, the “situationaldynamic spectral editing platform” can edit or create the “spectralrecipe” through the software application to construct an edited“situational dynamic spectrum program” that achieves (or satisfies) aspecific emotional effect. This “situational dynamic spectrum program”can also be uploaded to the external private cloud 6153 in the cloud 610and public cloud 6155, forming a database of “situational dynamicspectrum programs” that achieve (or satisfy) specific emotional effects.

Next, the editing process of the “situational dynamic spectrum program”in step 520 is described in detail. Please refer to FIG. 5b , whichshows the editing process of the situational dynamic spectrum editingplatform of the present invention. As shown in step 5210, the clientterminal 630 downloads the “spectral recipe” stored in the “sharingplatform” established in step 470 to the editing device used by theclient terminal 630 through the internet to the management controlmodule 611 in the cloud 610, for example, the editing device can be acomputer or a smartphone or a workstation, one or more “spectral recipe”is connected to the software as a service (SaaS) or platform as aservice (PaaS) configured in the cloud 610 through the editing device ofthe client terminal 630 in the system, afterwards, as shown in step5220, through the SaaS or PaaS system configured on the cloud, set thelighting parameters of a specific color temperature (that is, a specificmood) for the downloaded “spectral recipe”, wherein the setting items ofthe lighting parameters include the generation time of the spectrum, thelatitude and longitude of the spectrum, the brightness of the spectrum,the contrast of the spectrum, the flicker rate of the spectrum, etc.,can be adjusted and set, and the above-mentioned adjustment methods arethe same as the aforementioned methods of the present invention,including, replacing the “spectral recipe” in order of light scenes, orreplace the light scene in the “spectral recipe”, or delete a specificlight scene in the “spectral recipe”, or add a new light scene in the“spectral recipe”, etc., because these adjustment methods are all hasalready been explained, so it will not be repeated here. For example,when the user downloads a spectral combination of a multi-light scene asthe “spectral recipe” for emotional adjustment of happiness (4,000 K),the multispectral brightness and the multispectral contrast can befinely adjusted, and the spectral flicker rate in the second-stage Balimultispectral combination can also be adjusted at the same time, and thelighting sequence or lighting time of the aforementioned three-stagemultispectral combination can also be adjusted or consider the latitudeand longitude of the spectrum or the multispectral combination providedby the time of day, for example, add a multispectral combination at4,000 K color temperature in Cannes, France, or delete the beach inMonaco through a SaaS or PaaS system. The multispectral combinationabove is changed to the multispectral combination at 4,000 K colortemperature in Miami Beach, USA. For example, when the user or clientterminal 630 downloads a “spectral recipe” for a spectral combination ofa multi-light scene, and uses the SaaS or PaaS system to perform thecombination of other light scenes, the above adjustment and changeprocess can also go to step 510 The “human centric lighting parameterdatabase” stored in the memory module 617 is used to combine otheremotions (color temperature). The color temperature of the serene moodof the segment is used as the end stage of the lighting.

Next, as shown in step 5230, the relationship between the contextfunction and the “spectral recipe” is edited. In step 5230, the“spectral recipe” that has been adjusted or set in step 5220 is editedin relation to the specific context function that the user or clientterminal 630 wants to achieve, wherein, the relationship is divide thespecific situational function you want to achieve into multiple blocks,and each of these blocks corresponds to a light scene in the “spectralrecipe”, for example, in step 5210, the user downloads a “spectralrecipe” for a happy, excited and amusement multi-light scene, and whenthe user or client terminal 630 finally wants to achieve a goodsituational effect in the conference room (wherein, The so-called goodconference situation effect, for example, the client terminal 630chooses to be in the conference process, hoping that all theparticipants can stay relaxed at the beginning, stay focused during thediscussion, and stay happy at the conclusion). The original “spectralrecipe” can be adjusted to the “spectral recipe” of multi-light scenessuch as relaxation, concentration and amusement through step 5220, andin step 5230, the user or client terminal 630 divides the meetingprocess into openings, discussing and conclusion three situationalblocks, and then, the three situational blocks of opening, discussionand conclusion are corresponding to the “spectral recipe” of multi-lightscenes of relaxation, concentration and amusement, so that the wholemeeting can be The context of the process is linked to the “spectralrecipe” of the multi-light scene in the conference room. Next, as shownin step 5240, after the user or client terminal 630 completes the“spectral recipe” correlation between the context of the conferenceprocess and the multi-light scene, and then adds “time setting” to thecontext block, it can complete a “situational dynamic spectrum program”with the function of conference situation, for example, setting the timefor the opening, discussing and conclusion of the meeting to 5 minutes,15 minutes and 10 minutes, as shown in FIG. 5c , can complete the“situational dynamic spectrum program with meeting context function”.Obviously, the “situational dynamic spectrum program” obtained throughthe editing process in FIG. 5b can be stored in the memory module 617 orthe external private cloud 6153 or the public cloud 6155 through step530. Afterwards, these “situational dynamic spectrum programs” stored inthe external private cloud 6153 can be provided for their own use as“situational dynamic spectrum programs” with automatically adjustableand intelligent human centric lighting. For example, when the user orclient terminal 630 chooses to use a conference “situational dynamicspectrum program”, the spectrum in the conference room can beautomatically adjusted during the conference. Of course, the conference“situation dynamic spectrum program” edited by the client terminal 630can also be stored in the public cloud 6155, so that business activitiesthat are opened to other users through the cloud 610 can be achieved.Obviously, at this time, in step 530, in addition to the various“spectral recipe” downloaded from step 470, it also includes“situational dynamic spectrum programs”, therefore, it can be stored inthe cloud database established in step 530. Provide users with humancentric lighting. In addition, it should be emphasized that in thisembodiment, the editing of the “situational dynamic spectrum program” ofmulti-light scenes includes a combination of multi-light scenes with asingle emotion and a combination of multi-light scenes with multipleemotions. Of course, it also includes the specific emotions in themulti-light scene combination can also be combined using the multi-lightscene, which is not limited in the present invention.

In addition, in the editing process of FIG. 5b above, another embodimentcan also be selected, that is, the client terminal 630 downloads the“spectral recipe” stored in the “sharing platform” established in step470 to the editing device used by the client terminal 630 through theinternet to the management control module 611 in the cloud 610, andthen, the user or client terminal 630 can select to edit the desiredspecial situation setting function through SaaS or PaaS system (that is,first distinguish multiple blocks of specific situation functions), andthen associate the desired special situation setting with the downloaded“human centric lighting parameter database”, so as to complete thecorrelation editing between multiple situation blocks and correspondingemotions (color temperature), so as to form a multi emotional multilight scene combination. For example, the editor has first divided themeeting process into three blocks: opening, discussing and conclusion,and then went to the “human centric lighting parameter database” storedin the memory module 617 to select the “spectral recipe” correspondingto the multi light scene formed by the corresponding emotions such asrelaxation, concentration and amusement, or select the correspondingamusement “spectral recipe” for focused and relaxed multi light scenes.Since the way of travel relevance editing is the same, it will not berepeated in this embodiment.

Next, the present invention provides another preferred embodiment of anautomatically adjustable intelligent human centric lighting method.Since the “situational dynamic spectrum program” constructed in step 530is the result obtained by editing by individual client terminals 630, inorder to achieve better effects, it is necessary to consider the lightstimulation effects of different users on the “spectral recipe”, and/orneed to consider whether the lighting hardware configuration indifferent fields can achieve the light stimulation effect of “spectralrecipe”, which need to be adjusted.

Next, as shown in steps 550 and 570, the user or editor adjusts the“spectral recipe” in the “situational dynamic spectrum program” in orderto meet emotional needs. First, the user or client terminal 630 hasdownloaded a “situational dynamic spectrum program” from the externalprivate cloud 6153 or public cloud 6155, and this “situational dynamicspectrum program” can be a “spectral recipe” for a multi-emotional andmulti-light scene, or a “spectral recipe” for a multi-light scene with asingle emotion. Next, the user or client terminal 630 needs to be in a“specific environment” to execute the selected “situational dynamicspectrum program”, wherein, in the embodiment of the present invention,the “specific environment” is divided into three types. The aspect, asshown in step 570, includes: a closed lighting system, an intelligentlighting field, and a portable human centric lighting device. When the“specific environment” is a closed lighting system, wherein the closedlighting system is a closed control room with multiple light-emittingdevices (for example, a closed cavity that can isolate external light),it can It is provided that one or more users can receive the selected“situational dynamic spectrum program” in the closed cavity to performthe “spectral recipe” irradiation, as shown in step 571. In the processof spectral lighting, the present invention provides a function withcontrol mode setting. For example, the multi-light scene can becontrolled by the App on the mobile device used by the user or theclient terminal 630 or the control module in the closed cavity, forexample, under the influence of an environment with ambient light, the“spectral recipe” can be adjusted for the selected “situational dynamicspectrum program”. The adjustment methods includetime/longitude/latitude/brightness/flashing rate, etc., as shown in step540. In addition, when the “specific environment” is an intelligentlighting field, the intelligent lighting field is a field with multiplelight-emitting devices that can accommodate multiple people, such as aconference room, a classroom, a kind of office place, a kind of socialplace, or a kind of factory, etc., so that multiple users can receivethe “situational dynamic spectrum program” in the intelligent lightingfield to perform “spectral recipe” lighting, as shown in step 573. Inthe process of spectral illumination, the controller, user or clientterminal 630 of the field can control the selected “situational dynamic”through the application (App) on the mobile device used or the controlmodule in the field “spectral program” to adjust “spectral recipe”, forexample, under the influence of an ambient light environment, or underthe influence of the number of people in the field, to adjust the“spectral recipe”, the adjustment methods include:time/latitude/longitude/brightness/flashing rate, etc., as shown in step540. And, when the “specific environment” is a mobile portable lightingdevice, the mobile portable human centric lighting device is a virtualdevice related to the metaverse, such as: virtual reality (VR), mixedreality (MX) or an extended reality (XR) device, the user can accept theselected “situational dynamic spectrum program” through the virtualdevice to perform the “spectral recipe” irradiation, as shown in step575. In the process of spectral illumination, the user or clientterminal 630 can adjust the “spectral recipe” through the App on themobile device or the control module in the virtual device, for example,in an environment with ambient light. Under the influence, the “spectralrecipe” can be adjusted for the selected “situational dynamic spectrumprogram”, and the adjustment methods includetime/latitude/longitude/brightness/flashing rate, etc., as shown in step540.

During the operation of the above steps 540, 550 and 570, it is obviousthat the default value of the “spectral recipe” is adjusted for the“specific environment” where the user is located. In the process ofperforming this default value adjustment, the ambient light informationcan be transmitted to the user or the user through the wirelesscommunication device through the ambient light sensor 650 (as shown inFIG. 3 or FIG. 6) set in the “specific environment”. It is anapplication (App) on the mobile device of the client terminal 630 or acontrol module in the “specific environment”, which is used as areference for adjusting the default value of the “spectral recipe”. Inaddition, the occupancy sensor 660 (as shown in FIG. 3 or FIG. 6) set inthe “specific environment” can also transmit the information of thenumber of people in the environment to the mobile device of the user orclient terminal 630 through the wireless communication device. Theoccupancy sensor 660 can be a vibration sensor, and the frequency ofvibration can be used to determine the number of people The occupancysensor 660 may also be a temperature sensor, and the number of people isjudged by the ambient temperature. In addition, the occupancy sensor 660may also be a camera system, which judges the number of people throughartificial intelligence (AI) face recognition. In addition, theoccupancy sensor 660 can also be a gas concentration detector fordetecting changes in the concentration of oxygen (O₂) or carbon dioxide(CO₂), to judge the effect of the user's spectral irradiation. When thetemperature increases and the carbon dioxide (CO₂) concentration alsoincreases, it is judged that the spectral irradiation achieves thedesired emotional effect. Obviously, through the operation of step 540,step 550 and step 570, a “situational dynamic spectrum program” that canbe automatically adjusted for intelligent human centric lighting can beformed.

The present invention then provides another preferred embodiment of anautomatically adjustable intelligent human centric lighting method. Itis to further provide some sensing devices to feedback whether the userachieves the required emotional effect after being irradiated by the“spectral recipe” of the “situational dynamic spectrum program”. Thesesensing devices include contact physiological sensors (e.g., step 561)or non-contact optical sensors (e.g., step 563). Among them, the contacttype physiological sensor is configured on each user to measure theuser's heartbeat, blood pressure, pulse, blood oxygen concentration orelectrocardiogram, etc., to determine whether the user meets therequired emotion. The non-contact optical sensor can be configured inthe light environment where the user is located to measure theilluminance, color temperature, spectrum, color rendering index, etc.

As shown in step 580, after the user has performed the “spectral recipe”of the specific “situational dynamic spectrum program” in the “specificenvironment”, an algorithm will be used to determine whether the currentspectral irradiation process has reached the user's mood need. Wherein,the algorithm in step 580 may be a ratio of the signals between theuser's physiological signals (including: heartbeat, blood pressure,pulse and respiration rate) obtained through an algorithm, and thisratio is used to determine whether the specific emotional needs are met.Therefore, after the calculation processing of the management controlmodule 611, a database of physiological signal ratios relative tovarious emotions is established and stored in the memory module 617 inthe cloud 610 or the internal private cloud 6151. for example, when theuser is illuminated by the “situational dynamic spectrum program” ofhappy emotions for a period, the heartbeat, blood pressure and bloodoxygen are getting back to the App on the mobile device or the “specificenvironment” through the contact physiological sensor in step 561. Atthis time, the App on the mobile device or the control module in the“specific environment” calculates a proportional value from the feedbackdata through an algorithm, and then transmits this proportional value tothe management control module 611 through the internet, compare theratio value stored in the memory module 617 or the internal privatecloud 6151 through the management control module 611. For example, ifthe ratio value calculated by the algorithm falls between 1.1 to 1.15,and the management control module 611 determines that the probability ofthis ratio value reaching a happy mood is 80%, and the probability ofreaching a happy mood is 20%. If we judge whether the probability ofachieving the effect is 75%, the management control module 611 willjudge that the user has reached the required happiness after lightingthrough the “spectral recipe” of the selected “situational dynamicspectrum program” and will stop the irradiation program after the“situational dynamic spectrum program” completes the irradiationprogram. Then, in step 590, the “spectral recipe” data of the current“situational dynamic spectrum program” is stored in the internal privatecloud 6151, the external private cloud 6153 or the public cloud 6155 inthe cloud 610. If it is judged that after the user is illuminated by the“spectral recipe” of the selected “situational dynamic spectrumprogram”, the ratio value calculated by the algorithm has only a 50%probability of reaching the happy mood, which means that the happy moodrequired by the user has not yet been achieved. Currently, it isnecessary to return to step 550, after adjusting the “spectral recipe”of the selected “situational dynamic spectrum program” through thecontrol mode of step 540, perform the lighting program again, and passthe contact method of step 561. The physiological sensor gets back theuser's heartbeat, blood pressure and blood oxygen to the App on themobile device or the control module in the field after the ratiocalculated by the algorithm, and then transmits the ratio to the clouddatabase through the internet at a time and communicates with the cloud.The proportions in the database are compared until the desired happinessemotion is reached. Obviously, in the storage process of step 590, itwill also be stored in step 530 at the same time, so at this time, inthe cloud database established in step 530. In addition to the various“spectral recipe” downloaded from step 470, it also includes the“situational dynamic spectrum program” adjusted by the algorithm.Therefore, storing in the cloud database of the “situation dynamicspectrum program” established in step 530 can provide a more effective“situation dynamic spectrum program” for the user to perform humancentric lighting. In addition, it should be emphasized that in thisembodiment, the editing of the “situational dynamic spectrum program” ofmulti-light scenes includes a combination of multi-light scenes with asingle emotion and a combination of multi-light scenes with multipleemotions. Of course, it also includes the specific emotions in themulti-light scene combination can also be combined using the multi-lightscene, which is not limited in the present invention.

The intelligent human centric lighting system or method provided by thepresent invention can judge whether the user can judge or feel whetherthe effect has been achieved after the illumination of the “spectralrecipe” selected by the user through the feedback signal. The solutionprovided by the present invention is to judge through the user's actualphysiological signal. Therefore, the above embodiment of usingphysiological signals as an algorithm is only an example to let thepublic know the implementation of the technical means of the presentinvention, so it should not be a limiting condition of the presentinvention within the scope of rights. The invention should emphasizethat the scope of the “algorithm” of the present invention is if theindividual comparison is carried out through the user's physiologicalsignals, or the data in the cloud 610 database is further compared afterprocessing the physiological signals.

According to the above-mentioned intelligent human centric lightingmethod that can be automatically adjusted, the present invention furtherprovides an intelligent human centric lighting system for commercialoperation, as shown in FIG. 6. The intelligent human centric lightingsystem 100 for commercial operation of the present invention includes: acloud 610, a management control module 611, a lighting field terminal620 for intelligent lighting, and a client terminal 630. The devicesconfigured in the lighting field terminal 620 include: a light-emittingdevice or LED lamps group 621, at least one occupancy sensor 660, atleast one ambient light sensor 623, and a switch device 640. Thelighting field terminal 620 includes a “specific environment”. Accordingto FIG. 5a , the “specific environment” can be divided into threefields, including: a closed space that can be used by multiple people oran intelligent lighting field domain, as well as mobile portable humancentric lighting devices for personal use or enclosed spaces.

First, FIG. 6 discloses an intelligent human centric lighting system600A for commercial operation, which can be applied to an embodimentused by multiple people. The client can use the portable communicationdevice to download the “spectral recipe” or “situational dynamicspectrum program” to the cloud 610 through the internet and use theportable communication device to activate the LED lamps group 621 forhuman centric lighting, in order to form an intelligent human centriclighting system that can be automatically adjusted. Wherein, in thisembodiment, the client may be at the remote end, or may be at thespecific environment end at the near end. When the client is remote, theinternet is the Artificial Intelligence of Things (AIoT) formed by theInternet of Things (IoT) and Artificial Intelligence (AI). When theclient is at the near end, the internet is a wireless communicationprotocol formed by a gateway, including Wi-Fi or Bluetooth.

When a plurality of users has been distributed in a closed space orintelligent lighting field, the portable communication device can carryout specific “spectral recipe” or “situational dynamic spectrum program”human centric lighting for the starting LED lamps group 621. The closedlighting system is a closed space with a plurality of light-emittingdevices (for example, a closed cavity that can isolate external light),which can provide one or more users to receive human centric lighting inthe closed cavity. The intelligent lighting field is a field withmultiple light-emitting devices that can accommodate multiple people,such as a conference room, a classroom, an office, a social place or afactory, which can provide multiple users to receive human centriclighting in the intelligent lighting field.

In addition, the LED lamps group 621 can be further configured in aclosed space or in an intelligent lighting field. When multiple usersperform human centric lighting in the closed space, the closed space canprovide a space that is isolated from external environmentalinterference, allowing users to immerse themselves in the selected“spectral recipe” or “situational dynamic spectrum program”. At the sametime, in order to enable people to achieve the desired effect faster dueto lighting, the contact physiological sensor configured on each usercan also be used to measure the user's heartbeat, blood pressure, pulse,blood oxygen concentration or electrocardiogram, etc., to determinewhether the user has achieved the required emotion. In addition, facerecognition can also be performed through the vibration frequency,ambient temperature, ambient carbon dioxide concentration detected bythe occupancy sensor 660 and the background ambient light sensor 650configured in the intelligent lighting field, and the ambient carbondioxide concentration, spectrum, The light intensity, flashing rate, andcolor temperature are transmitted to the management control module 611in the cloud 610 through the Artificial Intelligence of Things (AIoT)for calculation, so as to determine whether the user has achieved theset effect. Similarly, in the process of spectral illumination, the“spectral recipe” of the multi-light scene can be adjusted through theApp on the mobile device used by the client terminal 630 or the controlmodule in the intelligent lighting field, for example, when the ambientlight sensor When the 650 detects the influence of ambient light, it canadjust the “spectral recipe” of the selected “situational dynamicspectrum program”. The adjustment methods include time, latitude andlongitude, brightness, flashing rate, etc. show the operation process ofstep 540, step 550, step 570 and step 580).

Next, FIG. 6 further discloses an embodiment of an intelligent humancentric lighting system 600A for commercial operation as shown, appliedto personal use. The user can use the portable communication device todownload the “spectral recipe” or “situation dynamic spectrum program”to the cloud 610 through the internet and activate the mobile portablehuman centric lighting device through the portable communication deviceto perform human activities. Due to lighting, to form an intelligenthuman centric lighting system that can be automatically adjusted.Especially when the user has worn the portable human centric lightingdevice on the user's eyes, the portable communication device can be usedto activate the LED lamps group 621 configured in the portable humancentric lighting device. A specific “spectral recipe” or “situationaldynamic spectrum program” for human centric lighting. Wherein, theportable human centric lighting device is a virtual device related tothe metaverse, such as a Virtual Reality (VR), Mixed Reality (MX) orExtended Reality (XR) device, which can provide a single user receiveshuman centric lighting through a virtual device.

In addition, in order to enable the human centric lighting of the mobileportable human centric lighting device to achieve the desired effectfaster, the contact type physiological sensor configured on the user'sbody can also be used to measure the user's heartbeat, blood pressure,pulse, blood oxygen concentration or electrocardiogram, etc., todetermine whether the user has the required emotion. Similarly, in theprocess of spectral irradiation, the “spectral recipe” of themulti-light scene can be adjusted through the App on the mobile deviceused by the client terminal 630 or the control module in the closedcavity (for details, please refer to step 540, step 550, step 570 andstep 580 during the operation).

In a preferred embodiment, the configuration of the LED lamps group 621can be configured according to the customized requirements through thehardware service database of step 420 and the software service databaseof step 440. Finally, the portable communication device in the automaticadjustable intelligent human centric lighting system of the presentinvention can be an intelligent phone, a tablet device or a workstation.The portable communication device can download an application (APP)containing intelligent human centric lighting from the ArtificialIntelligence of Things (AIoT) to the management control module 611.Through this app, the user can connect with the public cloud in thecloud 610, and then select the desired “spectral recipe” or “dynamicspectrum program” from the public cloud for human centric lighting. Atthe same time, through this app, the LED lamps group 621 can also beremotely turned on or off through the short-range communicationprotocol, to control the spectrum to achieve the effect of human centriclighting. Among them, if the user confirms that those “spectral recipe”or “situational dynamic spectrum programs” are effective, he candownload these “spectral recipe” or “situational dynamic spectrumprograms” to the portable communication device of the client, and thenconfigure the switching device 640 of the client, You can directly openthe “spectral recipe” or “situational dynamic spectrum program” forhuman centric lighting without internet connection, which allows usersto quickly enter the human centric lighting program.

The above-mentioned intelligent human centric lighting system that canbe adjusted automatically is to establish a database of the brain's“blood oxygen-level dependent response increase” condition through theintelligent human centric lighting system. After the database is editedby the spectral recipe, a cloud database of multispectral light-emittingdevices is constructed. The cloud database can provide users to set theemotional needs of the brain to be achieved in the intelligent humancentric lighting system, and the intelligent human centric lightingsystem can judge or suggest the operation logic of the lightdistribution equation. Lighting field and movable human centric lightingdevice. After that, when the user experiences the light situation, theintelligent human centric lighting system algorithm is used to determinethe user's physiological and psychological state. If the emotional needsof the brain have not been fulfilled, the “spectral recipe” program willbe continuously modified through the feedback signal of the wirelessdevice, and after re-adjusting the “spectral recipe”, it will bere-verified whether the expected emotional needs have been met. If thebrain reaches the emotional needs, it will provide a “spectral recipe”or “situational dynamic spectrum program” formed by lighting that meetsthe user's emotional needs to carry out the lighting process. Obviously,the intelligent human centric lighting method and system disclosed bythe present invention can make the human centric lighting effect of theemotional needs of the brain can be commercialized and benefit moreusers without the need to use fMRI.

Finally, it should be emphasized once that the above is only a betterembodiment of the present invention and is not used to limit the scopeof the rights of the present invention. At the same time, the abovedescription should be clear to and implemented by those with generalknowledge in the relevant technical field. Therefore, other equivalentchanges or modifications not separated from the concept disclosed in thepresent invention should be included in the scope of patent claims ofthe present invention.

What is claimed is:
 1. An editing method of a dynamic spectrum program,comprises: downloading a spectral recipe is to download the spectralrecipe with a plurality of light scenes with a specific colortemperature or at least one specific color temperature to the editingdevice through the internet, and connecting the editing device with thesoftware as a service system or a platform as a service systemconfigured in the cloud; performing a correlation editing between thespecific function and the spectral recipe, wherein the editing device isprovided for dividing the specific function to be achieved into aplurality of blocks through the software as a service system or theplatform as a service system, and corresponds the blocks to the spectralrecipe of the plurality of light scenes respectively; and forming afunctional dynamic spectrum program is to configure the plurality ofblocks for a corresponding time to form the dynamic spectrum program. 2.The editing method of dynamic spectrum program according to claim 1,further comprising: before performing the correlation editing,performing the setting of specific emotional parameters, and the editingdevice is provided for adjusting or setting the lighting parameters ofthe downloaded spectral recipe of the light scene through the softwareas a service system or the platform as a service system
 3. The editingmethod of dynamic spectrum program according to claim 1, furthercomprising: performing the setting of specific emotional parameters withthe editing device after performing the correlation editing, and theediting device adjusts or setting the lighting parameters of thespectral recipe of the downloaded light scene through the software as aservice system or the platform as a service system
 4. The editing methodof dynamic spectrum program according to claim 1, wherein the lightingparameter setting further comprises changing the light scene sequence inthe spectral recipe, changing the light scene in the spectral recipe,deleting the light scene in the spectral recipe or adding a new lightscene in the spectral recipe
 5. The editing method of dynamic spectrumprogram according to claim 1, wherein the corresponding time hasdifferent time intervals.
 6. A human centric lighting method forsituational dynamic spectrum program, comprises: constructing asituational dynamic spectrum program database is to edit the spectralrecipe of the multi light scene to achieve a specific color temperatureand the specific function to be achieved, and the correlation editing isto divide the specific function to be achieved into multiple situationalblocks through the cloud, correspond the situational blocks to the multilight scene respectively, and add time to the situational blocks, form asituational dynamic spectrum program and store it in the cloud database;selecting a situational dynamic spectrum program is that the userconnects with the cloud through an intelligent communication device, andthen selects the situational dynamic spectrum program that the userwants to achieve a specific emotion from the cloud database; executinghuman centric lighting is to start the multispectral light-emittingdevice configured in the field with the lighting parameters in theselected situational dynamic spectrum program in a specific field toemit a specific color temperature of the multi spectrum, so as toperform human centric lighting on the user; adjusting the spectralrecipe when judging the human centric lighting is not reach the effectof the specific emotion, the spectral recipe is adjusted, and the useradjusts the lighting parameters in the specific spectral recipe selectedby the user through the intelligent communication device; and storingthe adjusted situational dynamic spectrum program is to store thelighting parameters in the situational dynamic spectrum program selectedand adjusted by the user into the cloud database when the effect of thespecific emotion has been reached after the user performs human centriclighting.
 7. The human centric lighting method of the situationaldynamic spectrum program according to claim 6, wherein when therelevance editing is performed, the relevance editing is performedthrough the editing device through the software as a service system orthe platform as a service system.
 8. The human centric lighting methodof the situational dynamic spectrum program according to claim 6,wherein the lighting parameters may include the spectrum, lightintensity, flicker rate or color temperature of the lighting.
 9. Thehuman centric lighting method of the situational dynamic spectrumprogram according to claim 6, wherein the lighting parameters includethe lighting time or the generation time of the spectrum.
 10. A humanfactor illumination method for situational dynamic spectrum program,comprises: constructing a situational dynamic spectrum program databaseis to edit the spectral recipe of the multi light scene to achieve aspecific color temperature and the specific function to be achieved, andthe correlation editing is to divide the specific function to beachieved into multiple situational blocks through the cloud, correspondthe situational blocks to the multi light scene respectively, and addtime to the situational blocks, Form a situational dynamic spectrumprogram and store it in the cloud database; selecting a situationaldynamic spectrum program is that the user connects with the cloudthrough an intelligent communication device, and then selects thesituational dynamic spectrum program that the user wants to achieve aspecific emotion from the cloud database; executing human centriclighting is to start the multispectral light-emitting device configuredin the field with the lighting parameters in the selected situationaldynamic spectrum program in a specific field to emit a specific colortemperature of the multi spectrum, so as to perform human centriclighting on the user; judging whether the human centric lighting reachesthe effect of specific emotion is to calculate the physiological signalmeasured by the contact physiological sensor configured on the user, soas to judge whether the human centric lighting reaches the effect ofspecific emotion; and storing the situational dynamic spectrum program,and storing the corresponding lighting parameters of the spectral recipeof the situational dynamic spectrum program into the cloud database whenjudging that the human centric lighting has reached the effect of thespecific emotion.
 11. The human centric lighting method of thesituational dynamic spectrum program according to claim 10, comprises:judging the human centric lighting is whether reach the effect of thespecific emotion, the spectral recipe is adjusted, and the user adjuststhe lighting parameters in the selected situational dynamic spectrumprogram through the intelligent communication device.
 12. The humancentric lighting method of the situational dynamic spectrum programaccording to claim 10, wherein the physiological signal includesheartbeat, blood pressure, pulse or respiratory rate.
 13. The humancentric lighting method of the situational dynamic spectrum programaccording to claim 10, wherein when the relevance editing is performed,the relevance editing is performed through the editing device throughthe software as a service system or the platform as a service system.14. The human centric lighting method of the situational dynamicspectrum program according to claim 10, wherein the lighting parametersmay include the spectrum, light intensity, flicker rate or colortemperature of the lighting.
 15. The human centric lighting method ofthe situational dynamic spectrum program according to claim 10, which ischaracterized in that the lighting parameters include the lighting timeor the generation time of the spectrum.
 16. The human centric lightingmethod of the situational dynamic spectrum program according to claim10, wherein the specific field includes a closed lighting system, anintelligent lighting field or a portable human centric lighting device.17. The human centric lighting method of the situational dynamicspectrum program according to claim 16, wherein the closed lightingsystem is a closed cavity that can isolate external light.
 18. The humancentric lighting method of the situational dynamic spectrum programaccording to claim 16, wherein the intelligent lighting field is ameeting room, a classroom, an office place, a social place or a factory.19. The human centric lighting method of the situational dynamicspectrum program according to claim 16, wherein the portable humancentric lighting device is a virtual device related to the metauniverse.
 20. The human centric lighting method of the situationaldynamic spectrum program according to claim 19, wherein t the virtualdevice related to the meta universe includes a virtual reality (VR),mixed reality (MX) or an extended reality (XR) device.